Handheld electromechanical surgical instruments

ABSTRACT

A surgical instrument includes a power pack, an outer shell housing configured to selectively encase the power pack, and an adapter assembly configured to selectively couple the outer shell housing to a loading unit. The outer shell housing includes a motor and a drive shaft coupled to and rotatable by the motor. The outer shell housing includes a drive member supported in a distal portion thereof. The drive member is configured to selectively couple to the drive shaft. The adapter assembly has a drive member supported in its proximal end. The drive member of the adapter assembly is configured to selectively couple to the drive member of the outer shell housing such that rotation of the drive shaft actuates movement of the drive member of the adapter assembly via the drive member of the outer shell housing.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of and priority to U.S. ProvisionalPatent Application No. 62/265,631, filed Dec. 10, 2015, the entiredisclosure of which is incorporated by reference herein.

BACKGROUND

1. Technical Field

The present disclosure relates to surgical instruments. Morespecifically, the present disclosure relates to handheldelectromechanical surgical instruments for performing surgicalprocedures.

2. Background of Related Art

One type of surgical instrument is a linear clamping, cutting andstapling instrument. Such an instrument may be employed in a surgicalprocedure to resect a cancerous or anomalous tissue from agastro-intestinal tract. Conventional linear clamping, cutting andstapling instruments include a pistol grip-styled structure having anelongated shaft and distal portion. The distal portion includes a pairof scissors-styled gripping elements, which clamp the open ends of thecolon closed. In this instrument, one of the two scissors-styledgripping elements, such as the anvil portion, moves or pivots relativeto the overall structure, whereas the other gripping element remainsfixed relative to the overall structure. The actuation of thisscissoring mechanism (the pivoting of the anvil portion) is controlledby a grip trigger maintained in the handle.

In addition to the gripping elements, the distal portion also includes astapling mechanism. The fixed gripping element of the scissoringmechanism includes a staple cartridge receiving region and a mechanismfor driving the staples up through the clamped end of the tissue againstthe anvil portion, thereby sealing the previously opened end. Thegripping elements may be integrally formed with the shaft or may bedetachable such that various scissoring and stapling elements may beinterchangeable.

A number of surgical instrument manufacturers have developed productlines with proprietary powered drive systems for operating and/ormanipulating the surgical instrument. In many instances the surgicalinstruments include a powered handle assembly, which is reusable, and adisposable end effector or the like that is selectively connected to thepowered handle assembly prior to use and then disconnected from the endeffector following use in order to be disposed of or in some instancessterilized for re-use.

Many of the existing end effectors for use with many of the existingpowered handle assemblies are driven by a linear force. For example, endeffectors for performing endo-gastrointestinal anastomosis procedures,end-to-end anastomosis procedures and transverse anastomosis procedures,each typically require a linear driving force in order to be operated.As such, these end effectors cannot be directly attached to handleassemblies that use a rotary motion to deliver power or the like.

In order to make the linear driven end effectors compatible with poweredsurgical handle assemblies that use a rotary motion to deliver power, aneed exists for a way to convert rotation originating in the handleassembly into linear motion for driving the operations of the attachedend effector. Typically, adapters that intercouple an end effector witha powered handle assembly are used to provide this conversion ofrotation to translation.

Accordingly, a need exists for alternative ways of converting therotational motion originating in the handle assemblies into linearmotion.

SUMMARY

In one aspect of the present disclosure, a surgical instrument isprovided, which includes a power pack, an outer shell housing, and anadapter assembly. The power pack includes a motor and a drive shaftcoupled to and rotatable by the motor. The outer shell housing isconfigured to selectively encase the power pack therein and includes afirst drive member supported in a distal portion of the outer shellhousing. The first drive member is configured to selectively couple tothe drive shaft. The adapter assembly has a proximal end configured toselectively couple to the outer shell housing, and a distal endconfigured to couple to a loading unit. The adapter assembly has asecond drive member supported in the proximal end. The second drivemember is configured to selectively couple to the first drive membersuch that rotation of the drive shaft actuates the second drive memberthrough the first drive member.

In some embodiments, the outer shell housing may be transitionablebetween an open configuration and a closed configuration. In the openconfiguration, the power pack may be insertable and/or removable fromthe outer shell housing. In the closed configuration, the power pack maybe enclosed within the outer shell housing. The outer shell housing mayhave a proximal portion pivotably coupled to the distal portion of theouter shell housing such that in the open configuration, a portion ofthe proximal portion of the outer shell housing is spaced from acorresponding portion of the distal portion of the outer shell housing.

In some embodiments, in the closed configuration, the portion of theproximal portion of the outer shell housing may be connected to thecorresponding portion of the distal portion of the outer shell housing.In the closed configuration, the drive shaft may be operably connectedto the first drive member. In the open configuration, the drive shaftmay be disconnected from the first drive member.

In some embodiments, rotation of the drive shaft may axially move thefirst drive member when the first drive member is operably connected tothe drive shaft of the power pack.

In some embodiments, the drive shaft may be a lead screw. The firstdrive member of the outer shell housing may be an elongated nutthreadingly engaged to the lead screw such that rotation of the leadscrew axially moves the elongated nut relative to the lead screw. Thefirst drive member may include a nut threadingly engaged to the leadscrew, and a post extending from the nut. The post may have a matingpart configured to detachably mate with a corresponding mating part ofthe second drive member such that rotation of the lead screw translatesthe first drive member therealong to translate the second drive member.

In some embodiments, the surgical instrument may further include acoupling gear configured to interconnect the drive shaft and the firstdrive member. The drive shaft may include a first bevel gear configuredto operably engage the coupling gear. The coupling gear may include asecond bevel gear in operable engagement with the first bevel gear, anda spur gear extending from the second bevel gear and in operableengagement with the first drive member.

In some embodiments, the first drive member may be a longitudinal rackhaving teeth in operable engagement with the spur gear of the couplinggear such that rotation of the first bevel gear axially moves thelongitudinal rack. The first drive member may include two rackspivotably joined to one another. Each rack may have teeth in operableengagement with the spur gear of the coupling gear such that rotation ofthe first bevel gear axially moves at least one of the two racks.

In some embodiments, the first drive member may be an elongated ribbonincluding a proximal end and a distal end. The proximal end of theribbon is disposed about the spur gear and defines a plurality of slitsfor receipt of teeth of the spur gear. The distal end of the ribbon isdisposed within a linear track defined in the outer shell housing suchthat rotation of the coupling gear rotates the proximal end of theribbon to axially move the distal end of the ribbon through the lineartrack.

In some embodiments, the second drive member may have a proximal endconfigured for snap fit engagement with a distal end of the drive memberof the outer shell housing.

In another aspect of the present disclosure, a handle assembly isprovided, which includes a power pack and an outer shell housing. Thepower pack includes a motor and a drive shaft coupled to and rotatableby the motor. The outer shell housing is configured to selectivelyencase the power pack therein and includes a drive member supported in adistal portion of the outer shell housing. The drive member isconfigured to selectively couple to the drive shaft of the power packand a drive member of an adapter assembly. The drive shaft is configuredto actuate movement of the drive member of the outer shell housing uponrotation of the drive shaft.

In yet another aspect of the present disclosure, an outer shell housingfor selectively encasing a power pack therein is provided. The outershell housing includes a proximal portion defining a cavity therein, anda distal portion defining a cavity therein. The distal portion ispivotably coupled to the proximal portion between an open configuration,in which a portion of the proximal portion is spaced from acorresponding portion of the distal portion, and a closed configuration,in which the portion of the proximal portion is connected to thecorresponding portion of the distal portion. The outer shell housingfurther includes a drive member supported in the distal portion. Thedrive member is configured to selectively interconnect a drive shaft ofa power pack and a drive member of an adapter assembly.

In some embodiments, in the closed configuration, the proximal portionand the distal portion may cooperatively define an internal cavityconfigured for encasing a power pack. In the open configuration, a powerpack may be insertable and/or removable from the outer shell housing.

The present disclosure relates to electromechanical surgical instrumentsfor performing surgical procedures.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments of the present disclosure are described herein withreference to the accompanying drawings, wherein:

FIG. 1 is a perspective view of a handheld surgical instrument includinga handle assembly, an adapter assembly, and a surgical loading unit, inaccordance with an embodiment of the present disclosure;

FIG. 2 is a perspective view of the handle assembly of FIG. 1;

FIG. 3 is a front perspective view, with parts separated, of the handleassembly of FIG. 2 including an outer shell housing and a power pack;

FIG. 4A is a side view of the surgical instrument of FIG. 1 illustratingthe outer shell housing of FIG. 3 in an open configuration

FIG. 4B is a side view of the surgical instrument of FIG. 1 illustratingthe outer shell housing of FIG. 3 in the open configuration with thepower pack disposed therein;

FIG. 4C is a side view of the surgical instrument of FIG. 1 illustratingthe outer shell housing of FIG. 3 in a closed configuration;

FIG. 5 is a side, cross-sectional view of one embodiment of a driveassembly that extends longitudinally through the power pack of FIG. 3,the outer shell housing of FIG. 3, and the adapter assembly of FIG. 1;

FIG. 6 is a side, cross-sectional view of another embodiment of a driveassembly that extends longitudinally through the power pack of FIG. 3,the outer shell housing of FIG. 3, and the adapter assembly of FIG. 1;

FIG. 7 is a side, cross-sectional view of yet another embodiment of adrive assembly that extends longitudinally through the power pack ofFIG. 3, the outer shell housing of FIG. 3, and the adapter assembly ofFIG. 1;

FIG. 8A is a side view of yet another embodiment of a drive assemblythat extends longitudinally through the power pack of FIG. 3, the outershell housing of FIG. 3, and the adapter assembly of FIG. 1;

FIG. 8B is front view of the drive assembly of FIG. 8A;

FIG. 9 is a perspective view of yet another embodiment of a driveassembly that extends longitudinally through the power pack of FIG. 3,the outer shell housing of FIG. 3, and the adapter assembly of FIG. 1;and

FIG. 10 is a perspective view of yet another embodiment of a driveassembly that extends longitudinally through the power pack of FIG. 3,the outer shell housing of FIG. 3, and the adapter assembly of FIG. 1.

DETAILED DESCRIPTION OF EMBODIMENTS

Embodiments of the presently disclosed surgical instruments includinghandle assemblies, adapter assemblies, and drive assemblies, aredescribed in detail with reference to the drawings, in which likereference numerals designate identical or corresponding elements in eachof the several views. As used herein the term “distal” refers to thatportion of the surgical instrument, or component thereof, farther fromthe user, while the term “proximal” refers to that portion of thesurgical instrument, or component thereof, closer to the user.

With reference to FIG. 1, a surgical instrument, in accordance with anembodiment of the present disclosure, is generally designated as 10, andis in the form of a powered hand held electromechanical instrumentconfigured for performing various surgical functions, for example,stapling and cutting tissue. Surgical instrument 10 includes a handleassembly 100 configured for selective connection with an adapterassembly 200, and, in turn, adapter assembly 200 is configured forselective connection with end effectors or single use loading units(“SULU's”) 400. As described in detail below, surgical instrument 10 mayinclude a variety of drive assemblies, for example, a drive assembly 300shown in FIG. 5, configured to transfer motion originating from handleassembly 100, through adapter assembly 200, and to SULU 400.

As illustrated in FIGS. 1-4C, handle assembly 100 of surgical instrument10 includes an outer shell housing 110 and a power pack 101 configuredto be selectively received and substantially encased by outer shellhousing 110. Outer shell housing 110 includes a proximal portion orproximal half-section 110 a and a distal portion or distal half-section110 b. Half-sections 110 a, 110 b of outer shell housing 110 arepivotably connected to one another by a hinge 116 located along an upperedge of distal half-section 110 b and proximal half-section 110 a. Whenjoined, proximal and distal half-sections 110 a, 110 b define a shellcavity 110 c therein in which power-pack 101 is selectively situated.Proximal and distal half-sections 110 a, 110 b are divided along a planethat is perpendicular to a longitudinal axis “X” of adapter assembly200. Each of proximal and distal half-sections 110 a, 110 b includes arespective upper shell portion 112 a, 112 b, and a respective lowershell portion 114 a, 114 b. Lower shell portions 112 a, 112 b define asnap closure feature 118 for selectively securing lower shell portions112 a, 112 b to one another and for maintaining outer shell housing 110in a closed condition.

Proximal half-section 110 a is sized and shaped to house a majority ofpower pack 101 therein. Proximal half-section 110 a of shell housing 110supports a right-side control button 36 a and a left-side control button36 b. Right-side control button 36 a and left-side control button 36 bare capable of being actuated upon application of a corresponding forcethereto or a depressive force thereto.

Distal half-section 110 b of outer shell housing 110 covers a distalfacing portion of power pack 101 when outer shell housing 110 is in theclosed configuration, as shown in FIG. 4C. Distal half-section 110 b ofouter shell housing 110 non-rotatably supports a drive member 312 ofdrive assembly 300 therein, as will be described in detail below withreference to FIG. 5. Distal half-section 110 b defines a connectingportion 120 configured to accept a corresponding drive coupling assembly(not shown) of adapter assembly 200. Specifically, distal half-section110 b of outer shell housing 110 has a recess 122 that receives aportion (not shown) of the drive coupling assembly (not shown) ofadapter assembly 200 when adapter assembly 200 is mated to handleassembly 100. Connecting portion 120 of distal half-section 110 bdefines a pair of axially extending guide rails 120 a, 120 b projectingradially inward from inner side surfaces thereof. Guide rails 120 a, 120b assist in rotationally orienting adapter assembly 200 relative tohandle assembly 100 when adapter assembly 200 is mated to handleassembly 100. Connecting portion 120 of distal half-section 110 bdefines three apertures 122 a, 122 b, 122 c formed in a distally facingsurface thereof and which are arranged in a common plane or line withone another. Connecting portion 120 of distal half-section 110 b alsodefines an elongate slot 124 to contain a connector 166 also formed inthe distally facing surface thereof. Connecting portion 120 of distalhalf-section 110 b further defines a female connecting feature 126formed in a surface thereof. Female connecting feature 126 selectivelyengages with a male connecting feature (not shown) of adapter assembly200. It is contemplated that distal half-section 110 b may assume avariety of shapes that are each configured for non-rotatably housing adrive member of a drive assembly, for example, drive member 312 of driveassembly 300 shown in FIG. 5.

Distal half-section 110 b of outer shell housing 110 supports a distalfacing toggle control button 130. Toggle control button 130 is capableof being actuated in a left, right, up and down direction uponapplication of a corresponding force thereto or a depressive forcethereto. Distal half-section 110 b of outer shell housing 110 supports aright-side pair of control buttons 32 a, 32 b; and a left-side pair ofcontrol button 34 a, 34 b. Right-side control buttons 32 a, 32 b andleft-side control buttons 34 a, 34 b are capable of being actuated uponapplication of a corresponding force thereto or a depressive forcethereto.

Outer shell housing 110 is fabricated from a polycarbonate or similarpolymer, and is clear or transparent or may be overmolded. In someembodiments, outer shell housing 110 may be fabricated from any suitablematerial that can be sterilized, for example, by way of autoclaving.

With reference to FIGS. 3-4C, power-pack 101 of handle assembly 100 isconfigured for receipt within outer shell housing 110 and for poweringthe functions of surgical instrument 10. Power-pack 101 of handleassembly 100 includes an inner handle housing 150 having a lower housingportion 144 and an upper housing portion 148 extending from and/orsupported on lower housing portion 144. Lower housing portion 144 andupper housing portion 148 are separated into a proximal half-section 150a and a distal half-section 150 b connectable to proximal half-section150 a by a plurality of fasteners. When joined, proximal and distalhalf-sections 150 a, 150 b define an inner handle housing 150 having aninner housing cavity (not shown) therein in which a power-pack coreassembly (not shown) is situated. The power-pack core assembly isconfigured to control the various operations of surgical instrument 10.

Inner handle housing 150 of power pack 101 provides a housing in whichthe power-pack core assembly is situated. The power-pack core assemblyincludes a battery circuit (not shown), a controller circuit board (notshown) and a rechargeable battery (not shown) configured to supply powerto any of the electrical components of handle assembly 100. Thecontroller circuit board includes a motor controller circuit board (notshown), a main controller circuit board (not shown), and a first ribboncable (not shown) interconnecting the motor controller circuit board andthe main controller circuit board.

The power-pack core assembly further includes a motor “M” electricallyconnected to the controller circuit board and the battery. It iscontemplated that the power-pack core assembly may include more than onemotor, for example, a second motor (not shown) and a third motor (notshown). Motor “M” is disposed between the motor controller circuit boardand the main controller circuit board. The power-pack core assembly hasa motor shaft or drive shaft 304 (also see FIG. 5) coupled to androtatable by motor “M.”

Motor “M” is controlled by a motor controller. The motor controller isdisposed on the motor controller circuit board and is, for example,A3930/31K motor drivers from Allegro Microsystems, Inc. The A3930/31Kmotor drivers are designed to control a 3-phase brushless DC (BLDC)motor with N-channel external power MOSFETs, such as motor “M”. Each ofthe motor controllers is coupled to a main controller disposed on themain controller circuit board. The main controller is also coupled tomemory, which is also disposed on the main controller circuit board. Themain controller is, for example, an ARM Cortex M4 processor fromFreescale Semiconductor, Inc, which includes 1024 kilobytes of internalflash memory. The main controller communicates with the motorcontrollers through an FPGA, which provides control logic signals (e.g.,coast, brake, etc.). The control logic of the motor controller thenoutputs corresponding energization signals to motor “M” usingfixed-frequency pulse width modulation (PWM).

Rotation of the motor shafts by the motors of power pack 101 function todrive shafts and/or gear components of adapter assembly 200 in order toperform the various operations of surgical instrument 10. For example,motor “M” of power-pack 101 may be configured to drive shafts and/orgear components of outer shell housing 110, which drive correspondingdriven shafts and/or gear components of adapter assembly 200 in order toselectively move tool assembly 404 (FIG. 1) of SULU 400 relative toproximal body portion 402 of SULU 400, to rotate SULU 400 about alongitudinal axis “X”, to move cartridge assembly 408 relative to anvilassembly 406 of SULU 400, and/or to fire staples from within cartridgeassembly 408 of SULU 400.

With reference to FIGS. 1-4C, adapter assembly 200 of surgicalinstrument 10 is configured to transfer an axial translation of drivenshaft 304 (FIG. 3), which is disposed in outer shell housing 110, toSULU 400. Adapter assembly 200 includes an outer knob housing 202 and anouter tube 206 extending from a distal end of knob housing 202. Knobhousing 202 and outer tube 206 are configured and dimensioned to housethe components of adapter assembly 200. Outer tube 206 is dimensionedfor endoscopic insertion. In particular, outer tube 206 is passablethrough a typical trocar port, cannula or the like. Knob housing 202 isdimensioned to not enter the trocar port, cannula or the like. Knobhousing 202 is configured and adapted to connect to connecting portion120 of outer shell housing 110 of handle assembly 100.

With reference to FIGS. 5-10, various embodiments of a drive assembly ofsurgical instrument 10 are illustrated. Each drive assembly extendslongitudinally through power pack 101 of handle assembly 100, throughouter shell housing 110 of handle assembly 110, and through adapterassembly 200. The drive assemblies of FIGS. 5-10 are configured totransfer rotational motion originating from motor “M” of power pack 101into axial translation of a drive member, for example, drive member 312(FIG. 5), disposed within outer shell housing 110. This motion, in turn,is transferred to a drive member 322 (FIG. 5) disposed within adapterassembly 200, to ultimately effect surgical functions of surgicalloading unit 400. As such, rotational motion originating from motor “M”of power pack 101 is converted into axial translation (i.e., movementalong longitudinal axis “X”) of the drive assembly at a location withinouter shell housing 110. In some embodiments, rotational motion ofcomponents of the drive assembly may be converted into axial translationof components of the drive assembly at a location other than outer shellhousing 110, for example, within power pack 101 or within adapterassembly 200.

With reference to FIG. 5, one embodiment of a drive assembly 300 isshown and generally includes a first drive assembly 300 a disposedwithin power pack 101, a second drive assembly 300 b disposed withinouter shell housing 110, and a third drive assembly 300 c disposedwithin adapter assembly 200. First drive assembly 300 a of power pack101 is operably coupled to second drive assembly 300 b of outer shellhousing 110 upon closing outer shell housing 110 with power pack 101disposed therein, and second drive assembly 300 b of outer shell housing110 is operably coupled to third drive assembly 300 c of adapterassembly 200 upon attaching adapter assembly 200 to handle assembly 100.

First drive assembly 300 a of power pack 101 includes a first driveshaft 302 coupled to and extending from motor “M” of power pack 101, anda second drive shaft or lead screw 304. First drive shaft 302 has agear, for example, a spur gear 306, non-rotatably coupled thereto.Second drive shaft 304 has a proximal portion 304 a and a distal portion304 b. Proximal portion 304 a of second drive shaft 304 has a gear 308non-rotatably coupled thereto that is in operable engagement or meshingengagement with gear 306 of first drive shaft 302 such that rotation offirst drive shaft 302, caused by actuation of motor “M,” drives arotation of second drive shaft 304 within power pack 101. Distal portion304 b of second drive shaft 304 has a threaded outer surface 310configured for a detachable threading engagement with a threadedinternal surface 314 of a drive member 312 of second drive assembly 300b of outer shell housing 110.

In one embodiment, as shown in FIG. 6, instead of first drive assembly300 a having two drive shafts as illustrated in FIG. 5, first driveassembly 300 a of power pack 101 may have one drive shaft in the form ofa lead screw 304 that extends directly and distally from motor “M.”

With continued reference to FIG. 5, second drive assembly 300 b isdisposed within distal-half section 110 b of outer shell housing 110 ofhandle assembly 100 and extends along longitudinal axis “X” of surgicalinstrument 10. Second drive assembly 300 b includes a drive member, suchas, for example, an elongated nut 312 that is non-rotatably supported indistal half-section 110 b of outer shell housing 110. Elongated nut 312has a proximal portion 312 a and a distal portion 312 b. Proximalportion 312 a of second drive assembly 300 b has a threaded internalsurface 314 that defines a bore 316 longitudinally therethrough. Uponclosing outer shell housing 110 with power pack 101 disposed therein,distal portion 304 b of second drive shaft 304 of first drive assembly300 a engages threaded internal surface 314 of drive member 312 ofsecond drive assembly 300 b. To operatively couple first and seconddrive assemblies 300 a, 300 b to one another, second drive shaft 304 isrotated, which results in the threaded coupling between second driveshaft 304 of first drive assembly 300 a and elongated nut 312 of seconddrive assembly 300 b.

Distal portion 312 b of elongated nut 312 of second drive assembly 300 bis configured to releasably connect to third drive assembly 300 c ofadapter assembly 200 upon connecting knob housing 202 of adapterassembly 200 to distal half-section 110 b of outer shell housing 110. Inparticular, distal portion 312 b of elongated nut 312 may have a roundedjoint or ball 318. Joint or ball 318 of elongated nut 312 may projectdistally outside of distal half-section 110 b of outer shell housing110. Second drive assembly 300 b of outer shell housing 110 furtherincludes a biasing member or coil spring 320 disposed about elongatednut 312. Coil spring 320 resiliently biases elongated nut 312 in aproximal direction to assist in assembly of first drive assembly 300 awith second drive assembly 300 b. When first and second drive assemblies300 a, 300 b are operably connected to one another, a rotation of seconddrive shaft 304 of first drive assembly 300 a drives an axialtranslation of elongated nut 312 of second drive assembly 300 b.

With continued reference to FIG. 5, third drive assembly 300 c isdisposed within adapter assembly 200 and extends along longitudinal axis“X.” Third drive assembly 300 c includes a drive member 322 supported inknob housing 202 of adapter assembly 200 and may project proximallytherefrom. Drive member 322 of third drive assembly 300 c has a proximalend 322 a and a distal end 322 b. Proximal end 322 a of drive member 322of third drive assembly 300 c may be in the form of a collet that isconfigured to releasably receive joint 318 of elongated nut 312 ofsecond drive assembly 300 b. Collet 322 a has a pair of resilient arms324 that snap fittingly engage cutouts 319 defined in joint 318 ofelongated nut 312 of second drive assembly 300 b. Distal end 322 b ofdrive member 322 of third drive assembly 300 c is configured tooperatively couple to a component (not shown) of surgical loading unit400 (FIG. 1) and to operate a function or functions of surgical loadingunit 400. Third drive assembly 300 c further includes a biasing memberor coil spring 326 disposed about drive member 322. Coil spring 326resiliently biases drive member 322 in a proximal direction to assist inassembly of second drive assembly 300 b with third drive assembly 300 c.

To assemble surgical instrument 10, proximal and distal half-sections110 a, 110 b of outer shell housing 110 are pivoted away from oneanother to open outer shell housing 110 as described above withreference to FIGS. 4A-C. With outer shell housing 110 of handle assembly100 in the open configuration, power pack 101, which may be in anon-sterilized state, is inserted into outer shell housing 110, which issterile. Proximal and distal half-sections 110 a, 110 b of outer shellhousing 110 are pivoted toward one another to close outer shell housing110. Upon closing outer shell housing 110 with power pack 101 situatedtherein, first and second drive assemblies 300 a, 300 b engage oneanother.

In particular, with reference to FIG. 5, during a closure of outer shellhousing 110 (See FIG. 4C), second drive shaft 304 of first driveassembly 300 a of power pack 101 engages elongated nut 312 of seconddrive assembly 300 b of outer shell housing 110 to move elongated nut312 in a distal direction against the proximally-oriented bias impartedon elongated nut 312 by coil spring 320. In this state, first and seconddrive assemblies 300 a, 300 b are not yet operatively coupled to oneanother. To operatively couple first and second drive assemblies 300 a,300 b, motor “M” of power pack 101 is actuated to rotate second driveshaft 304 of first drive assembly 300 a. Rotation of second drive shaft304 of first drive assembly 300 a causes threaded outer surface 310 ofsecond drive shaft 304 to catch threaded internal surface 314 ofelongated nut 312 to ultimately cause second drive shaft 304 to bedisposed within bore 316 of elongated nut 312.

With first drive assembly 300 a of power pack 101 operatively coupled tosecond drive assembly 300 b of outer shell housing 110, third driveassembly 300 c of adapter assembly 200 may then be operatively coupledto second drive assembly 300 b of outer shell housing 110. It iscontemplated that adapter assembly 200 may be operatively coupled toouter shell housing 110 prior to operatively coupling power pack 101 toouter shell housing 110. To operatively couple adapter assembly 200 toouter shell housing 110, the drive coupling assembly (not shown) of knobhousing 202 of adapter assembly 200 is received within connectingportion 120 (FIG. 3) of distal half-section 110 b of outer shell housing110. Upon connecting knob housing 202 of adapter assembly 200 withdistal half-section 110 b of outer shell housing 110, collet 322 a ofdrive member 322 of adapter assembly 200 receives joint 318 of elongatednut 312 of outer shell housing 110 to operatively couple drive member322 of adapter assembly 200 to elongated nut 312 of outer shell housing110.

After surgical instrument 10 is assembled, operation of surgicalinstrument 10 may be performed. In particular, to effect surgicalfunctions of surgical loading unit 400, a motor, for example, motor “M”of power pack 101 is actuated, which rotates first drive shaft 302 ofpower pack 100, and in turn, rotates second drive shaft 304 of powerpack 101, via the interactions between gears 306, 308 of first andsecond drive shafts 302, 304, respectively. The rotation of second driveshaft 304 drives a proximal or distal longitudinal movement of elongatednut 312 of outer shell housing 110 due to second drive shaft 304 ofpower pack 101 being threadingly engaged to elongated nut 312 of outershell housing 110. Proximal or distal longitudinal movement of elongatednut 312 results in a corresponding motion of drive member 322 of adapterassembly 200 as a result of elongated nut 312 of outer shell housing 110being attached to drive member 322 of adapter assembly 200. Since distalend 322 b of drive member 322 of adapter assembly 200 is operativelyconnected to a working component(s) (not shown) of surgical loading unit400, the axial movement of drive member 322 of adapter assembly 200effects various functions of surgical loading unit 400, for example,opening or closing of its jaw members 406, 408, a stapling function,and/or a cutting function.

To disassemble surgical instrument 10, knob housing 202 of adapterassembly 200 may be manually detached from handle assembly 100, therebycausing joint 318 of elongated nut 312 of outer shell housing 110 todisengage collet 322 a of drive member 322 of adapter assembly 200.Prior to removing power pack 101 from outer shell housing 110, firstdrive assembly 300 a of power pack 101 is disengaged from second driveassembly 300 b. To disengage first and second drive assemblies 300 a,300 b from one another, motor “M” of power pack 101 is actuated torotate first drive shaft 302, and in turn, second drive shaft 304.Rotation of second drive shaft 304 of first drive assembly 300 a causessecond drive shaft 304 of first drive assembly 300 a to back out of bore316 of elongated nut 312 by pushing elongated nut 312 in a distaldirection. Second drive shaft 304 is rotated until its threaded outersurface 310 is out of threading engagement with threaded internalsurface 314 of elongated nut 312. After disengaging second drive shaft304 of power pack 101 from elongated nut 312 of outer shell housing 110,snap closure feature 118 of outer shell housing 110 is unsnapped andouter shell housing 110 is opened. With outer shell housing 110 in theopened configuration, as shown in FIG. 4B, power pack 101 can be removedfrom outer shell housing 110. Outer shell housing 110 may then bere-sterilized or re-cleaned for re-use.

With reference to FIG. 7, another embodiment of a drive assembly isillustrated, which is similar to drive assembly 300 described above withreference to FIG. 5, thus, to prevent unnecessary repetition only thedifferences between the embodiments are described. Drive assembly 500generally includes a drive shaft or lead screw 502 disposed within powerpack 101, a drive member 512 disposed within outer shell housing 110,and a drive member 522 disposed within adapter assembly 200. Lead screw502 of power pack 101 is operably coupled to drive member 512 of outershell housing 110 upon closing outer shell housing 110 with power pack101 disposed therein, and drive member 512 of outer shell housing 110 isoperably coupled to drive member 522 of adapter assembly 200 uponattaching adapter assembly 200 to handle assembly 100.

Lead screw 502 of drive assembly 500 is disposed within power pack 101and is coupled to and extends from motor “M” of power pack 101. Drivemember 512 of outer shell housing 110 is in the form of a couplingmember that is configured to convert a rotation of lead screw 502 ofpower pack 101 into a translation of drive assembly 500 within outershell housing 110. Coupling member 512 is restrained within power pack101 so as to prevent coupling member 512 from rotating therein. Couplingmember 512 of drive assembly 500 is disposed within outer shell housing110 and has a nut 512 a, and a post 512 b extending from nut 512 a. Nut512 a of coupling member 512 is configured to be threadingly engaged tolead screw 502 of power pack 101 such that rotation of lead screw 502 ofpower pack 101, caused by actuation of motor “M” of power pack 101,causes coupling member 512 of outer shell housing 110 to translate alonglead screw 502. Post 512 b of coupling member 512 has a first end 512 cand a second end 512 d and extends along an axis that is perpendicularto longitudinal axis “X” of surgical instrument 10. First end 512 c ofpost 512 b is monolithically formed with nut 512 a, but it iscontemplated that first end 512 c of post 512 b may be attached to nut512 a via any suitable engagement. Second end 512 b of post 512 b has amating part 514 configured for detachable mating with a correspondingmating part 524 of drive member 522 of adapter assembly 200. Mating part514 is a step or squared cutout defined in second end 512 d of post 512b. In some embodiments, mating part 514 of coupling member 512 may beany suitable male or female mating part.

Drive member 522 of drive assembly 500 is disposed within adapterassembly 200 and extends along longitudinal axis “X” of surgicalinstrument 10. Drive member 522 is an elongated shaft having a proximalend 522 a and a distal end 522 b. Proximal end 522 a of drive member 522has a mating part 524, similar to mating part 514 of coupling member 512outer shell housing 110. Mating part 524 of drive member 522 of adapterassembly 200 is configured for detachable mating with mating part 514 ofcoupling member 512 of outer shell housing 110. Distal end 522 b ofdrive member 522 of adapter assembly 200 is configured to operativelycouple to a component (not shown) of surgical loading unit 400 tooperate a function or functions of surgical loading unit 400.

To assemble surgical instrument 10, proximal and distal half-sections110 a, 110 b of outer shell housing 110 are pivoted away from oneanother to open outer shell housing 110. With outer shell housing 110 ofhandle assembly 100 in the open configuration, as shown in FIG. 4B,power pack 101, which may be in a non-sterilized state, is inserted intoouter shell housing 110, which is sterile. Proximal and distalhalf-sections 110 a, 110 b of outer shell housing 110 are pivoted towardone another to close outer shell housing 110. Upon closing outer shellhousing 110 with power pack 101 situated therein, drive assembly 500 isassembled.

In particular, during a closure of outer shell housing 110, lead screw502 of power pack 101 engages nut 512 a of coupling member 512 of outershell housing 110 to move coupling member 512 in a distal directionagainst a proximally oriented bias imparted on coupling member 512 by acoil spring (not shown). With drive assembly 500 in this state, leadscrew 502 of power pack 101 and coupling member 512 of outer shellhousing 110 are not yet operatively coupled to one another. Tooperatively couple lead screw 502 to coupling member 512, motor “M” ofpower pack 101 is actuated to rotate lead screw 502 of power pack 101.Rotation of lead screw 502 of power pack 101 causes a threaded outersurface of lead screw 502 to catch a threaded internal surface (notshown) of nut 512 a of coupling member 512 to ultimately cause leadscrew 502 to be disposed within nut 512 a of coupling member 512.

With lead screw 502 of power pack 101 operatively coupled to couplingmember 512 of outer shell housing 110, adapter assembly 200 may then beoperatively coupled to outer shell housing 110. It is contemplated thatadapter assembly 200 may be operatively coupled to outer shell housing110 prior to operatively coupling power pack 101 to outer shell housing110. To operatively couple adapter assembly 200 to outer shell housing110, the drive coupling assembly (not shown) of knob housing 202 ofadapter assembly 200 is received within connecting portion 120 (FIG. 3)of distal half-section 110 b of outer shell housing 110. Upon connectingknob housing 202 of adapter assembly 200 with distal half-section 110 bof outer shell housing 110, mating part 524 of drive member 522 ofadapter assembly 200 interlocks with mating part 514 of coupling member512 of outer shell housing 110 to operatively couple drive member 522 ofadapter assembly 200 to coupling member 512 of outer shell housing 110.

After drive assembly 500 of surgical instrument 10 is assembled,operation of surgical instrument 10 may be performed. In particular, toeffect surgical functions of surgical loading unit 400, motor “M” ofpower pack 101 is actuated, which rotates lead screw 502 of power pack101. Rotation of lead screw 502 of power pack 101 drives a proximal ordistal longitudinal movement of coupling member 512 of outer shellhousing 110 therealong. Proximal or distal longitudinal movement ofcoupling member 512 of outer shell housing 110 results in acorresponding motion of drive member 522 of adapter assembly 200 as aresult of coupling member 512 of outer shell housing 110 being attachedto drive member 522 of adapter assembly 200. Since distal end 522 b ofdrive member 522 of adapter assembly 200 is operatively connected toworking component(s) (not shown) of surgical loading unit 400, the axialmovement of drive member 522 of adapter assembly 200 effects variousfunctions of surgical loading unit 400, for example, opening or closingof its jaw members 406, 408, a stapling function, and/or a cuttingfunction.

To disassemble surgical instrument 10, knob housing 202 of adapterassembly 200 may be manually detached from handle assembly 100, therebycausing mating part 524 of drive member 522 of adapter assembly 200 todisengage mating part 514 of coupling member 512 of outer shell housing110. Prior to removing power pack 101 from outer shell housing 110, leadscrew 502 of power pack 101 is disengaged from coupling member 512 ofouter shell housing 110. To disengage lead screw 502 from couplingmember 512, motor “M” of power pack 101 is actuated to rotate lead screw502. Rotation of lead screw 502 of power pack 101 causes lead screw 502of power pack 101 to back out of nut 512 a of coupling member 512 whilepushing coupling member 512 in a distal direction. Rotation of leadscrew 502 of power pack 101 is continued until its threaded outersurface is out of threading engagement with the threaded internalsurface of nut 512 a of coupling member 512 of outer shell housing 110.After disengaging lead screw 502 of power pack 101 from coupling member512 of outer shell housing 110, snap closure feature 118 of outer shellhousing 110 is unsnapped and outer shell housing 110 is opened. Withouter shell housing 110 in the open configuration, power pack 101 can beremoved from outer shell housing 110.

With reference to FIGS. 8A and 8B, another embodiment of a driveassembly 600 is illustrated, similar to drive assemblies 300, 500described above with reference to FIGS. 5-7. Drive assembly 600generally includes a drive shaft assembly 602 disposed within power pack101, a drive member 612 disposed within outer shell housing 110, and adrive member 622 disposed within adapter assembly 200. Drive shaftassembly 602 of power pack 101 is operably coupled to drive member 612of outer shell housing 110 upon closing outer shell housing 110 withpower pack 101 disposed therein, and drive member 612 of outer shellhousing is operably coupled to the drive member (not shown) of adapterassembly 200 upon attaching adapter assembly 200 to handle assembly 100.

Drive shaft assembly 602 of drive assembly 600 is disposed within powerpack 101 and includes a drive shaft 604 coupled to and extending frommotor “M” of power pack 101, a first gear 606, and a second gear orcoupling gear 608. First gear 606 is non-rotatably coupled to driveshaft 604 and defines a rotation axis that is parallel to longitudinalaxis “X” of surgical instrument 10. First gear 606 is in the form of abevel gear, but in some embodiments, first gear 606 may be any suitablegear. Second gear or coupling gear 608 is in operable engagement ormeshing engagement with first gear 606. Coupling gear 608 defines arotation axis that is perpendicular to the rotation axis of first gear606. Coupling gear 608 is a compound bevel-spur gear. Specifically,coupling gear 608 includes a bevel gear 608 a and a spur gear 608 bextending from bevel gear 608 a. Bevel gear 608 a of coupling gear 608is in operable engagement with first gear 606 of drive shaft 604. Spurgear 608 b of coupling gear 608 is configured to be in operableengagement with drive member 612 of outer shell housing 110 upon closingouter shell housing 110 around power pack 101.

Drive member 612 of outer shell housing 110 is in the form of alongitudinal rack that is configured to convert a rotation of couplinggear 608 of power pack 101 into a translation of drive assembly 600within outer shell housing 110. Rack 612 of outer shell housing 110 hasa proximal portion 612 a and a distal portion (not explicitly shown) andextends along longitudinal axis “X” of surgical instrument 10. Proximalportion 612 a has a plurality of teeth 614 configured to operably engageor meshingly engage spur gear 608 b of second gear 608 such thatrotation of coupling gear 608 of power pack 101, caused by actuation ofmotor “M” of power pack 101, causes rack 612 of outer shell housing 110to axially translate. The distal end of rack 612 of outer shell housing110 is configured for detachable mating engagement with a mating part ofthe drive member (not shown) of adapter assembly 200. It is contemplatedthat the distal end of rack 612 and a proximal end of the drive memberof adapter assembly 200 releasably engage one another in a similarmanner as that described with reference to second and third driveassemblies 300 b, 300 c of FIG. 5. The distal end of the drive member ofadapter assembly 200 is configured to operatively couple tocomponent(s)(not shown) of surgical loading unit 400 to operate afunction or functions of surgical loading unit 400.

To assemble surgical instrument 10, proximal and distal half-sections110 a, 110 b of outer shell housing 110 are pivoted away from oneanother to open outer shell housing 110. With outer shell housing 110 ofhandle assembly 100 in the open configuration, power pack 101, which maybe in a non-sterilized state, is inserted into a sterilized outer shellhousing 110. Proximal and distal half-sections 110 a, 110 b of outershell housing 110 are pivoted toward one another to close outer shellhousing 110. Upon closing outer shell housing 110 with power pack 101situated therein, drive assembly 600 is assembled.

In particular, during a closure of outer shell housing 110, spur gear608 b of coupling gear 608 of power pack 101 engages teeth 614 of rack612 of outer shell housing 110. Adapter assembly 200 may then beoperatively coupled to outer shell housing 110 in a similar mannerdescribed above with reference to FIGS. 5-7. It is contemplated thatadapter assembly 200 may be operatively coupled to outer shell housing110 prior to operatively coupling power pack 101 to outer shell housing110.

After drive assembly 600 of surgical instrument 10 is assembled,operation of surgical instrument 10 may be performed. In particular, toeffect surgical functions of surgical loading unit 400, motor “M” ofpower pack 101 is actuated, which rotates first gear 606 of power pack101. Rotation of first gear 606 drives a rotation of coupling gear 608,which in turn drives a proximal or distal longitudinal movement of rack612 of outer shell housing 110. Proximal or distal longitudinal movementof rack 612 of outer shell housing 110 results in a corresponding motionof the drive member of adapter assembly 200 as a result of rack 612 ofouter shell housing 110 being attached to the drive member of adapterassembly 200. Since the distal end of the drive member of adapterassembly 200 is operatively connected to working component(s) (notshown) of surgical loading unit 400, the axial movement of the drivemember of adapter assembly 200 effects various functions of surgicalloading unit 400, for example, opening or closing of its jaw members406, 408, a stapling function, and/or a cutting function.

To disassemble surgical instrument 10, knob housing 202 of adapterassembly 200 may be manually detached from handle assembly 100, in asimilar manner described above with respect to FIGS. 5-7. Snap closurefeature 118 of outer shell housing 110 is unsnapped and outer shellhousing 110 is opened, as shown in FIG. 4B. With outer shell housing 110in the open configuration, power pack 101 can be removed from outershell housing 110.

With reference to FIG. 9, another embodiment of a drive assembly 700 isillustrated, similar to drive assemblies 300, 500, 600 described abovewith reference to FIGS. 5-8B. Drive assembly 700 generally includes adrive shaft assembly 702 disposed within power pack 101, a drive member712 disposed within outer shell housing 110, and a drive member (notshown) disposed within adapter assembly 200. Drive shaft assembly 702 ofpower pack 101 is operably coupled to drive member 712 of outer shellhousing 110 upon closing outer shell housing 110 with power pack 101disposed therein, and drive member 712 of outer shell housing 110 isoperably coupled to the drive member of adapter assembly 200 uponattaching adapter assembly 200 to handle assembly 100.

Drive shaft assembly 702 of drive assembly 700 is disposed within powerpack 101 and includes a drive shaft 704 coupled to and extending frommotor “M” of power pack 101, a first gear (not explicitly shown), and asecond gear or coupling gear 708. Drive shaft assembly 702 of power pack101 is similar to drive shaft assembly 602 described above withreference to FIGS. 8A and 8B, and will therefore not be described indetail herein.

Drive member 712 of outer shell housing is in the form of a plurality ofracks that are configured to convert a rotation of coupling gear 708 ofpower pack 101 into a translation of drive assembly 700 within outershell housing 110. Racks 712 of outer shell housing 110 are coupled toone another to form a train of racks. Each rack 712 may be coupled to anadjacent rack 712 by a ball and socket connection 714, a relativelyrigid tether, or any other suitable connection that permits racks 712 topivot relative to one another, but resists pivoting of racks 712relative to one another unless a threshold force is applied. As such,racks 712 will maintain a generally linear configuration if no force isacting on racks 712. Racks 712 each have a concave surface having teeth716 projecting therefrom. The toothed surface 716 of each rack 712 isconcave to cup coupling gear 708 of power pack 101 upon outer shellhousing 110 closing around power pack 101. Racks 712 are disposedbetween two plates or tracks 718 that are fixed within distalhalf-section 110 b of outer shell housing 110. Plates 718 prevent racks712 from buckling, thereby guiding racks 712 along longitudinal axis“X.”

Drive assembly 700 further includes a firing rod or shaft 720 extendingdistally from a distal-most rack 712 b. A distal end of firing rod 720of outer shell housing 110 is configured for detachable matingengagement with a mating part (not shown) of the drive member (notshown) of adapter assembly 200. It is contemplated that the distal endof firing rod 720 of outer shell housing 110 and a proximal end of thedrive member of adapter assembly 200 releasably engage one another in asimilar manner as that described with reference to second and thirddrive assemblies 300 b, 300 c of FIG. 5. The distal end of the drivemember of adapter assembly 200 is configured to operatively couple to acomponent(s)(not shown) of surgical loading unit 400 to operate afunction or functions of surgical loading unit 400.

To assemble surgical instrument 10, proximal and distal half-sections110 a, 110 b of outer shell housing 110 are pivoted away from oneanother to open outer shell housing 110. With outer shell housing 110 ofhandle assembly 100 in the open configuration, as shown in FIG. 4B,power pack 101, which may be in a non-sterilized state, is inserted intoa sterilized outer shell housing 110. Proximal and distal half-sections110 a, 110 b of outer shell housing 110 are pivoted toward one anotherto close outer shell housing 110. Upon closing outer shell housing 110with power pack 101 situated therein, drive assembly 700 is assembled.

In particular, during a closure of outer shell housing 110, the spurgear 708 of coupling gear of power pack 101 engages teeth 716 of aproximal-most rack 712 a of outer shell housing 110. Adapter assembly200 may then be operatively coupled to outer shell housing 110 in asimilar manner described above with reference to FIGS. 5-7. It iscontemplated that adapter assembly 200 may be operatively coupled toouter shell housing 110 prior to operatively coupling power pack 101 toouter shell housing 110.

After drive assembly 700 of surgical instrument 10 is assembled,operation of surgical instrument 10 may be performed. In particular, toeffect surgical functions of surgical loading unit 400, motor “M” ofpower pack 101 is actuated, which rotates first gear (not explicitlyshown) of power pack 101. Rotation of the first gear drives a rotationof second gear 708, which in turn drives a proximal or distallongitudinal movement of racks 712 of outer shell housing 110 throughtracks 718 of outer shell housing 110. Proximal or distal longitudinalmovement of racks 712 of outer shell housing 110 results in acorresponding motion of firing rod 720 of outer shell housing 110 andthe drive member (not shown) of adapter assembly 200 as a result offiring rod 720 of outer shell housing 110 being attached to the drivemember of adapter assembly 200. Since the distal end of the drive memberof adapter assembly 200 is operatively connected to a workingcomponent(s)(not shown) of surgical loading unit 400, the axial movementof the drive member of adapter assembly 200 effects various functions ofsurgical loading unit 400, for example, opening or closing of its jawmembers 406, 408, a stapling function, and/or a cutting function.

To disassemble surgical instrument 10, knob housing 202 of adapterassembly 200 may be manually detached from handle assembly 100, in asimilar manner described above with respect to FIGS. 5-7. Snap closurefeature 118 of outer shell housing 110 is unsnapped and motor “M” ofpower pack 101 is actuated until each of racks 712 are out of engagementwith second gear 708 of power pack 101 and proximal-most rack 712 a isdisposed distally of second gear 708 of power pack 101. Outer shellhousing 110 may then be opened. With outer shell housing 110 in the openconfiguration, as shown in FIG. 4B, power pack 101 can be removed fromouter shell housing 110.

With reference to FIG. 10, another embodiment of a drive assembly 800 isillustrated, similar to drive assembly 700 described above withreference to FIG. 9. Drive assembly 800 generally includes a drive shaftassembly 802 disposed within power pack 101, a drive member 812 disposedwithin outer shell housing 110, and a drive member (not shown) disposedwithin adapter assembly 200. Drive shaft assembly 802 of power pack 101is operably coupled to drive member 812 of outer shell housing 110 uponclosing outer shell housing 110 with power pack 101 disposed therein,and drive member 812 of outer shell housing 110 is operably coupled tothe drive member of adapter assembly 200 upon attaching adapter assembly200 to handle assembly 100, as will be described in detail below.

Drive shaft assembly 802 of drive assembly 800 is disposed within powerpack 101 and includes a drive shaft (not explicitly shown) coupled toand extending from motor “M” of power pack 101, a first gear 804, and asecond gear or coupling gear 808. Drive shaft assembly 802 of power pack101 is similar to drive shaft assembly 602 described above withreference to FIGS. 8A and 8B, and will therefore not be described infurther detail herein.

Drive member 812 of outer shell housing 110 is in the form of anelongated ribbon that is configured to convert a rotation of second gear808 of power pack 101 into a translation of drive assembly 800 withinouter shell housing 110. Ribbon 812 of outer shell housing 110 resistsbending or folding unless a threshold force is applied. As such, ribbon812 will maintain a generally linear configuration if no force is actingthereon. Ribbon 812 defines a plurality of slits 816 therein configuredfor receipt of teeth of spur gear 808 b of second gear 808 of power pack101. Ribbon 812 is disposed between two plates or tracks 818 that arefixed within distal half-section 110 b of outer shell housing 110.Tracks 818 prevent ribbon 812 from buckling, thereby guiding ribbon 812along longitudinal axis “X.”

A firing rod or shaft 820 extends distally from a distal end of ribbon812. A distal end of firing rod 820 of outer shell housing 110 isconfigured for detachable mating engagement with a mating part (notshown) of the drive member (not shown) of adapter assembly 200. It iscontemplated that the distal end of firing rod 820 and a proximal end ofthe drive member of adapter assembly 200 releasably engage one anotherin a similar manner as that described above with reference to second andthird drive assemblies 300 b, 300 c of FIG. 5. The distal end of thedrive member of adapter assembly 200 is configured to operatively coupleto a component(s)(not shown) of surgical loading unit 400 to operate afunction or functions of surgical loading unit 400.

To assemble surgical instrument 10, proximal and distal half-sections110 a, 110 b of outer shell housing 110 are pivoted away from oneanother to open outer shell housing 110, as shown in FIG. 4B. With outershell housing 110 of handle assembly 100 in the open configuration,power pack 101, which may be in a non-sterilized state, is inserted intoa sterilized outer shell housing 110. Proximal and distal half-sections110 a, 110 b of outer shell housing 110 are pivoted toward one anotherto close outer shell housing 110. Upon closing outer shell housing 110with power pack 101 situated therein, drive assembly 800 is assembled.

In particular, during a closure of outer shell housing 110, spur gear808 b of second gear 808 of power pack 101 are received within slits 816defined in ribbon 812 of outer shell housing 110. Adapter assembly 200may then be operatively coupled to outer shell housing 110 in a similarmanner described above with reference to FIGS. 5-7. It is contemplatedthat adapter assembly 200 may be operatively coupled to outer shellhousing 110 prior to operatively coupling power pack 101 to outer shellhousing 110.

After drive assembly 800 of surgical instrument 10 is assembled,operation of surgical instrument 10 may be performed. In particular, toeffect surgical functions of surgical loading unit 400, motor “M” ofpower pack 101 is actuated, which rotates first gear 804 of power pack101. Rotation of first gear 804 drives a rotation of second gear 808,which in turn causes ribbon 812 to wrap thereabout and drives a proximalor distal longitudinal movement of ribbon 812 of outer shell housing 110through tracks 818 of outer shell housing 110. Proximal or distallongitudinal movement of ribbon 812 of outer shell housing 110 resultsin a corresponding motion of firing rod 820 of outer shell housing 110and the drive member of adapter assembly 200 as a result of firing rod820 of outer shell housing 110 being attached to the drive member ofadapter assembly 200. Since the distal end of the drive member ofadapter assembly 200 is operatively connected to a workingcomponent(s)(not shown) of surgical loading unit 400, the axial movementof the drive member of adapter assembly 200 effects various functions ofsurgical loading unit 400, for example, opening or closing of its jawmembers 406, 408, a stapling function, and/or a cutting function.

To disassemble surgical instrument 10, knob housing 202 of adapterassembly 200 may be manually detached from handle assembly 100, in asimilar manner described above with respect to FIGS. 5-7. Snap closurefeature 118 of outer shell housing 110 is unsnapped and motor “M” ofpower pack 101 is actuated until ribbon 812 unravels from around secondgear 808 of power pack 101 and teeth of second gear 808 of power pack101 are removed from slits 816 of ribbon 812. Outer shell housing 110may then be opened. With outer shell housing 110 in the openconfiguration, power pack 101 can be removed from outer shell housing110.

It will be understood that various modifications may be made to theembodiments of the presently disclosed adapter assemblies. Therefore,the above description should not be construed as limiting, but merely asexemplifications of embodiments. Those skilled in the art will envisionother modifications within the scope and spirit of the presentdisclosure.

What is claimed is:
 1. A surgical instrument, comprising: a power packincluding: an inner handle housing; a motor disposed in the inner handlehousing; and a drive shaft partially disposed in the inner handlehousing and coupled to and rotatable by the motor; an outer shellhousing configured to encase the power pack therein, the outer shellhousing including a first drive member having a distal end disposedoutside of and distal of the inner handle housing of the power pack, thefirst drive member being supported in a distal portion of the outershell housing, the first drive member being configured to selectivelycouple to the drive shaft; and an adapter assembly having a proximal endconfigured to couple to a distal end of the outer shell housing, and adistal end configured to couple to a loading unit, the adapter assemblyhaving a second drive member supported in the proximal end, the seconddrive member being configured to selectively couple to the distal end ofthe first drive member such that rotation of the drive shaft actuatesthe second drive member through the first drive member, wherein thefirst drive member is non-rotatably supported by the distal portion ofthe outer shell housing such that the first drive member is preventedfrom rotating relative to the outer shell housing about a longitudinalaxis defined by the first drive member.
 2. The surgical instrumentaccording to claim 1, wherein the outer shell housing is transitionablebetween an open configuration, in which the power pack is at least oneof insertable or removable from the outer shell housing, and a closedconfiguration, in which the power pack is enclosed within the outershell housing.
 3. The surgical instrument according to claim 2, whereinthe outer shell housing has a proximal portion pivotably coupled to thedistal portion of the outer shell housing such that in the openconfiguration, a portion of the proximal portion of the outer shellhousing is spaced from a corresponding portion of the distal portion ofthe outer shell housing and in the closed configuration, the portion ofthe proximal portion of the outer shell housing is connected to thecorresponding portion of the distal portion of the outer shell housing.4. The surgical instrument according to claim 2, wherein in the closedconfiguration, the drive shaft is operably connected to the first drivemember and in the open configuration, the drive shaft is disconnectedfrom the first drive member.
 5. The surgical instrument according toclaim 1, wherein rotation of the drive shaft axially moves the firstdrive member when the first drive member is operably connected to thedrive shaft of the power pack.
 6. The surgical instrument according toclaim 1, wherein the drive shaft is a lead screw.
 7. The surgicalinstrument according to claim 6, wherein the first drive member of theouter shell housing is an elongated nut threadingly engaged to the leadscrew such that rotation of the lead screw axially moves the elongatednut relative to the lead screw.